Depth-Resolved EELS and Chemical State Mapping of N+-Implanted TiO2 Photocatalyst

Tomoko Yoshida; Shunsuke Muto; Jun Wakabayashi

doi:10.2320/matertrans.MD200712

This article has now been updated. Please use the final version.

Depth-Resolved EELS and Chemical State Mapping of N⁺-Implanted TiO₂ Photocatalyst

Tomoko Yoshida, Shunsuke Muto, Jun Wakabayashi

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Keywords: photocatalyst, visible-light response, ion implantation, electron energy loss spectroscopy, self-modeling curve resolution, energy-filtering transmission electron microscopy

JOURNAL RESTRICTED ACCESS Advance online publication

Article ID: MD200712

DOI https://doi.org/10.2320/matertrans.MD200712

The final version of this article is now available: Vol. 48 (2007) , No. 10 p.2580

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Abstract

We propose novel methods of depth-resolved EELS (DREELS) and chemical state mapping, and the techniques were applied to the cross-sectional TEM (XTEM) sample of N⁺ implanted TiO₂ catalyst. DREELS is realized by applying the Pixon deconvolution to a conventional energy-filtering TEM (EFTEM)-based spatially resolved EELS (EFTEM-SREELS), demonstrated by Kimoto et al. [J. Electron Microsc. 46 (1997) 369–374.]. And a self-modeling curve resolution (SMCR) technique in multivariate analysis enabled chemical state mapping from EFTEM-based spectrum imaging (EFTEM-SI) data sets. The methods successfully extracted the depth dependence of the N-K ELNES and separately displayed the spatial distributions of the constituent chemical states, whose spectral features were overlapped.

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